Power density boosting in uplink shared channels

ABSTRACT

A communications device transmits/receives data to/from a mobile communications network including one or more network elements forming a wireless access interface for transmitting/receiving the data. An up-link includes a shared channel for transmitting the data to the mobile communications network. A controller controls a transmitter and receiver to transmit to the mobile communications network a request to transmit data in a smaller number of frequency division multiplexed symbols than available on the shared channel, to receive from the mobile communications network an indication of a sub-set of the predetermined number of frequency division multiplexed symbols in which the communications device should transmit the data on the shared channel, and to transmit signals representing the data in the shared channel to occupy a smaller number of frequency division multiplexed symbols than the number of the predetermined number of frequency division multiplexed symbols of the time period of the shared channel.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is based on PCT filing PCT/EP2014/065310 filedJul. 16, 2014, and claims priority to European Patent Application 13 180489.0, filed in the European Patent Office on Aug. 14, 2013, the entirecontents of each of which being incorporated herein by reference.

Thus as shown in FIGS. 8a and 8b , the UE can transmit a pair of datasymbols in SC-FDMA symbols (3, 4, 5) or (4, 5, 6), which in one examplecan be interpreted as different information sets, which are called ‘Set1’ and ‘Set 2’ respectively. Then the position-based modulation optionsare as depicted in Table 1 below, where a BPSK-based example has beenused for simplicity of presentation but without loss of generality. Thisparticular flashbulb arrangement is most relevant to PUCCH format2/2a/2b which would use QPSK pairs instead of the BPSK pairs we haveused here for clarity. So by way of example, in FIG. 8a , an eNodeBdetecting nothing in SC-FDMA symbol 3, ‘0’ in SC-FDMA symbol 4 and ‘1’in SC-FDMA symbol 6 concludes that the actual information data beingconveyed is ‘101’. Upon detecting the transmission in FIG. 8b , theeNodeB concludes that the actual information data being conveyed is‘001’.

TECHNICAL FIELD OF THE DISCLOSURE

The present disclosure relates communications devices, infrastructureequipment for mobile communications networks, mobile communicationsnetworks and systems and methods of transmitting and receiving data viamobile communications networks.

BACKGROUND OF THE DISCLOSURE

Mobile communications systems continue to be developed to providewireless communications services to a greater variety of electronicdevices. In more recent years, third and fourth generation mobiletelecommunication systems, such as those based on the 3GPP defined UMTSand Long Term Evolution (LTE) architectures have been developed tosupport more sophisticated communications services to personal computingand communications devices than simple voice and messaging servicesoffered by previous generations of mobile telecommunication systems. Forexample, with the improved radio interface and enhanced data ratesprovided by LTE systems, a user may enjoy high data rate applicationssuch as mobile video streaming and mobile video conferencing that wouldpreviously only have been available via a fixed line data connection.The demand to deploy third and fourth generation networks is thereforestrong and the coverage area of these networks, i.e. geographiclocations where access to the networks is possible, is expected toincrease rapidly.

More recently it has been recognised that rather than providing highdata rate communications services to certain types of electronicsdevices, it is also desirable to provide communications services toelectronics devices that are simpler and less sophisticated. Forexample, so-called machine type communication (MTC) applications may besemi-autonomous or autonomous wireless communication devices which maycommunicate small amounts of data on a relatively infrequent basis. Someexamples include so-called smart meters which, for example, are locatedin a customer's house and periodically transmit information back to acentral MTC server data relating to the customer's consumption of autility such as gas, water, electricity and so on. Other examplesinclude applications to automotive technology and medical devices

As will be appreciated it is desirable to provide arrangements forreducing power consumption and therefore increasing battery life ofcommunications devices operating to communicate data via mobilecommunications networks.

SUMMARY OF THE DISCLOSURE

Embodiments of the present disclosure can provide in one example acommunications device, which transmits data to or receives data from amobile communications network. The mobile communications networkincludes one or more network elements which are arranged to form awireless access interface for transmitting and receiving the data. Thecommunications device comprises a transmitter unit configured totransmit signals representing the data on an up-link of the wirelessaccess interface to the mobile communications network and a receiverunit configured to receive signals representing the data transmitted ona down-link from the mobile communications network via the wirelessaccess interface. The wireless access interface provides a plurality ofcommunications resource elements across a frequency range for thedown-link and the up-link, the communications resource elements beingformed by dividing sub-carriers at different frequencies into aplurality of time periods, one or more of the sub-carriers beingprovided to form, in the time domain, frequency division multiplexedsymbols, each of the time periods comprising a predetermined number ofthe frequency division multiplexed symbols. The up-link includes ashared channel providing the communications resources for allocation tothe communications device by the mobile communications network fortransmitting the data on the up-link to the mobile communicationsnetwork. The shared channel provides communications resources which areshared with other communications terminals and comprising in the timedomain, the predetermined number of frequency division multiplexedsymbols in each time period for allocation to the communications device.A controller is configured to control the transmitter unit to transmitthe signals and the receiver unit to receive the signals to transmit orreceive the data. The controller is configured to control thetransmitter unit and the receiver unit to transmit to the mobilecommunications network a request to transmit data in a smaller number offrequency division multiplexed symbols than are available on the sharedchannel, to receive from the mobile communications network an indicationof a sub-set of the predetermined number of frequency divisionmultiplexed symbols in which the communications device should transmitthe data on the shared channel, and to transmit signals representing thedata in the shared channel to occupy a smaller number of frequencydivision multiplexed symbols than the number of the predetermined numberof frequency division multiplexed symbols of the time period of theshared channel.

By reducing a number of frequency division multiplexed symbols on whichthe signalling information is transmitted in the control channel to beless than the predetermined number of symbols available on the sharedchannel, embodiments of the present disclosure can provide acorresponding reduction in power consumed by the communications device.Accordingly there is an improvement in the battery life of thecommunications device. The term frequency division multiplexed symbolsis used to describe a time and frequency division multiplexing techniquesuch as OFDM or SC-FDMA which modulates sub-carriers on the frequencydomain and forms symbols from the modulated sub-carriers in the timedomain.

In one example, the controller is configured to transmit the signalsrepresenting the signalling information in the smaller number offrequency division multiplexed symbols within the time period of theshared channel starting at a different one of the predetermined numberof frequency division multiplexed symbols. Each of the differentstarting frequency division multiplexed symbols represents furtherinformation, which may in one example form part of the signallinginformation. Therefore by providing a variation in the starting positionof the signals representing the signalling information in a smallernumber of the predetermined number of frequency division multiplexedsymbols the reduction in communications capacity provided by thereduction in the number of symbols can be compensated by increasing thedata signalling capacity. This is achieved by varying the startingposition of the transmission of the signalling information.

Embodiments of the present technique can also be applied to thetransmission of data in a control channel of a mobile communicationsnetwork. In one example there is provided a communications device fortransmitting data to or receiving data from a mobile communicationsnetwork. The mobile communications network includes one or more networkelements which are arranged to form a wireless access interface fortransmitting and receiving the data. The communications device comprisesa transmitter unit configured to transmit signals representing the dataon an up-link of the wireless access interface to the mobilecommunications network and a receiver unit configured to receive signalsrepresenting the data transmitted on a down-link from the mobilecommunications network via the wireless access interface. The wirelessaccess interface provides a plurality of communications resourceelements across a frequency range for the down-link and the up-link, thecommunications resource elements being formed by dividing sub-carriersat different frequencies into a plurality of time periods, one or moreof the sub-carriers being provided to form, in the time domain,frequency division multiplexed symbols, each of the time periodscomprising a predetermined number of the frequency division multiplexedsymbols. The up-link includes a control channel for transmittingsignalling information from the communications device to the mobilecommunications network in accordance with a predetermined format inwhich signals which representing the signalling information occupy, inthe time domain, the predetermined number of frequency divisionmultiplexed symbols of the control channel. A controller is configuredto control the transmitter unit to transmit the signals and the receiverunit to receive the signals to transmit or receive the data. Thecontroller is configured to adapt the transmission of the signalsrepresenting the signalling information transmitted, by the transmitterunit, in the control channel to occupy a smaller number of thepredetermined number of frequency division multiplexed symbols of thetime period of the control channel.

In some examples the communications devices are reduced capabilitydevices such as MTC devices, such as smart meters or medical devices.

Various further aspects and embodiments of the disclosure are providedin the appended claims, including but not limited to, an infrastructureequipment (or network element of a mobile communications network), acommunications device and method of communicating to a communicationsdevice using a mobile communications network element.

BRIEF DESCRIPTION OF DRAWINGS

Embodiments of the present disclosure will now be described by way ofexample only with reference to the accompanying drawings in which likeparts are provided with corresponding reference numerals and in which:

FIG. 1 provides a schematic diagram illustrating an example of aconventional mobile communications system;

FIG. 2 provides a schematic diagram illustrating an arrangement ofchannels of a wireless access interface for ten down-link sub-frames ofa conventional LTE wireless access interface;

FIG. 3 provides a schematic diagram illustrating a conventional LTEdownlink radio sub-frame;

FIG. 4 provides a schematic illustration of an example arrangement foran uplink shared channel (PUSCH) with DM-RS symbols and normal orextended cyclic-prefix operation;

FIG. 5 is a schematic illustration of a sub-frame illustrating aposition of uplink control channels, PUCCH, and an up-link sharedchannel, PUSCH within one sub-frame of an up-link;

FIG. 6 is a schematic block diagram illustrating the formation of aPUCCH format 1/1a/1b;

FIG. 7 is a schematic block diagram illustrating an arrangement forforming a PUCCH format 2/2a/2b;

FIG. 8a is a schematic illustration of a transmission of signals withina control channel in accordance with one example of the presenttechnique; and FIG. 8b is a schematic illustration of the transmissionof signals within a control channel in accordance with another exampleof the present technique;

FIG. 9 is a part schematic block diagram part flow diagram illustratingoperations performed by a controller to generate signal transmissions inaccordance with the present technique;

FIG. 10a is a schematic illustration showing an arrangement fortransmissions of signals within a time slot of a sub-frame in a reducednumber of frequency division multiplexed symbols (SC-FDMA) symbols andin which a DM-RS symbol is transmitted in a first position A; FIG. 10bprovides a corresponding schematic illustration showing an arrangementfor transmission of signals in which the DM-RS symbol is in a secondposition B;

FIG. 11 is a schematic representation showing an example of an up-linkcontrol channel (PUCCH) transmission distributed across two physicalresource blocks;

FIG. 12 is a schematic representation of a sub-frame in whichtransmissions of signals representing data in an uplink shared channel(PUSCH) is varied within a smaller number of frequency divisionmultiplexed (SC-FDMA) symbols in accordance with the present technique;

FIG. 13a is a part schematic block diagram part flow diagramillustrating the transmission of permitted reduced timeslot formatswithin the PUSCH using a broadcast channel; FIG. 13b is a part schematicpart flow diagram illustrating an arrangement in which a reducedcapability device indicates to the eNodeB its desire to transmit signalsrepresenting data in a shared channel using a smaller number offrequency division multiplexed (SC-FDMA) symbols than are available;FIG. 13c is a part schematic block diagram part flow diagramillustrating a further example arrangement in which a PRACH is used tosignal a smaller number of frequency division multiplexed symbols whichcan be used by a communications device to transmit data on the sharedchannel; and FIG. 13d is a corresponding part schematic part flowdiagram illustrating a conventional transmission on a PRACH followed bythe grant of a communications resource with an indication of the formatwhich can be used to transmit signals in a smaller number of frequencydivision multiplexed (SC-FDMA) symbols than are available;

FIG. 14 is a schematic block diagram of an example mobile communicationssystem according to an example embodiment of the present technique;

FIG. 15 is a flow diagram illustrating the operation of a communicationsdevice transmitting in a control channel in accordance with the presenttechnique; and

FIG. 16 is a flow diagram illustrating the operation of a communicationsdevice transmitting data in a shared channel in accordance with thepresent technique.

DESCRIPTION OF EXAMPLE EMBODIMENTS Example Network

FIG. 1 provides a schematic diagram illustrating the basic functionalityof a conventional mobile communications system. In FIG. 1, a mobilecommunications network includes a plurality of base stations 101connected to a core network 102. Each base station provides a coveragearea 103 (i.e. a cell) within which data can be communicated to and fromcommunications devices 104. Data is transmitted from a base station 101to a communications device 104 within a coverage area 103 via a radiodownlink Data is transmitted from a communications device 104 to a basestation 101 via a radio uplink. The core network 102 routes the data toand from the base stations 104 and provides functions such asauthentication, mobility management, charging and so on. The basestations 101 provide a wireless access interface comprising the radiouplink and the radio downlink for the communications devices and formexamples of infrastructure equipment or network elements for the mobilecommunications network, and may be, for the example of LTE, an enhancedNode B (eNodeB Or eNB).

The term communications devices will be used to refer to acommunications terminal or apparatus which can transmit or receive datavia the mobile communications network. Other terms may also be used forcommunications devices such as personal computing apparatus, remoteterminal, transceiver device or user equipment (UE) which may or may notbe mobile.

Example Down-Link Configuration

Mobile telecommunications systems such as those arranged in accordancewith the 3GPP defined Long Term Evolution (LTE) architecture use anorthogonal frequency division multiplexing (OFDM) based radio accessinterface for the radio downlink (so-called OFDMA) and the radio uplink(so-called SC-FDMA). Data is transmitted on the radio uplink and on theradio downlink on a plurality of orthogonal sub-carriers. FIG. 2 shows aschematic diagram illustrating an OFDM based LTE downlink radio frame201. The LTE downlink radio frame is transmitted from an LTE basestation and lasts 10 ms. The downlink radio frame comprises tensub-frames, each sub-frame lasting 1 ms, and each sub-frame comprisestwo slots, each slot lasting 0.5 ms. A primary synchronisation signal(PSS) and a secondary synchronisation signal (SSS) are transmitted inthe first and sixth sub-frames (conventionally numbered as sub-frame 0and 5) of the LTE frame, in the case of frequency division duplex (FDD)system. A physical broadcast channel (PBCH) is transmitted in the firstsub-frame of the LTE frame. The PSS, SSS and PBCH are discussed in moredetail below.

FIG. 3 provides a schematic diagram providing a grid which illustratesthe structure of an example of a conventional downlink LTE sub-frame.The sub-frame comprises a predetermined number of symbols which aretransmitted over a 1 ms period. Each symbol comprises a predeterminednumber of orthogonal sub-carriers distributed across the bandwidth ofthe downlink radio carrier.

The example sub-frame shown in FIG. 3 comprises 14 symbols and 1200sub-carriers spaced across a 20 MHz bandwidth. The smallest unit onwhich data can be transmitted in LTE is twelve sub-carriers transmittedover one slot. For clarity, in FIG. 3, each individual resource elementis not shown, but instead each individual box in the sub-frame gridcorresponds to twelve sub-carriers transmitted on one symbol.

FIG. 3 shows resource allocations for four communications devices 340,341, 342, 343. For example, the resource allocation 342 for a firstcommunications device (UE 1) extends over five blocks of twelvesub-carriers, the resource allocation 343 for a second communicationsdevice (UE2) extends over six blocks of twelve sub-carriers and so on.

Control channel data is transmitted in a control region 300 of thesub-frame comprising the first n symbols of the sub-frame where n canvary between one and three symbols for channel bandwidths of 3 MHz orgreater and where n can vary between two and four symbols for channelbandwidths of 1.4 MHz. The data transmitted in the control region 300includes data transmitted on the physical downlink control channel(PDCCH), the physical control format indicator channel (PCFICH) and thephysical HARQ indicator channel (PHICH).

The PDCCH contains control data indicating which sub-carriers on whichsymbols of the sub-frame have been allocated to specific communicationsdevices (UEs). Thus, the PDCCH data transmitted in the control region300 of the sub-frame shown in FIG. 3 would indicate that UE1 has beenallocated the first block of resources 342, that UE2 has been allocatedthe second block of resources 343, and so on. In sub-frames where it istransmitted, the PCFICH contains control data indicating the duration ofthe control region in that sub-frame (i.e. between one and four symbols)and the PHICH contains HARQ (Hybrid Automatic Request) data indicatingwhether or not previously transmitted uplink data has been successfullyreceived by the network.

In certain sub-frames, symbols in a central band 310 of the sub-frameare used for the transmission of information including the primarysynchronisation signal (PSS), the secondary synchronisation signal (SSS)and the physical broadcast channel (PBCH) mentioned above. This centralband 310 is typically 72 sub-carriers wide (corresponding to atransmission bandwidth of 1.08 MHz). The PSS and SSS are synchronisationsequences that once detected allow a communications device 104 toachieve frame synchronisation and determine the cell identity of thebase station (eNodeB) transmitting the downlink signal. The PBCH carriesinformation about the cell, comprising a master information block (MIB)that includes parameters that the communications devices require toaccess the cell. The data transmitted to individual communicationsdevices on the physical downlink shared channel (PDSCH) can betransmitted in the remaining blocks of communications resource elementsof the sub-frame.

FIG. 3 also shows a region of PDSCH containing system information andextending over a bandwidth of R₃₄₄. Thus in FIG. 3 the central frequencycarries control channels such as the PSS, SSS and PBCH and thereforeimplies a minimum bandwidth of a receiver of a communications device.

The number of sub-carriers in an LTE channel can vary depending on theconfiguration of the transmission network. Typically this variation isfrom 72 sub carriers contained within a 1.4 MHz channel bandwidth to1200 sub-carriers contained within a 20 MHz channel bandwidth as shownin FIG. 3. As is known in the art, subcarriers carrying data transmittedon the PDCCH, PCFICH and PHICH are typically distributed across theentire bandwidth of the sub-frame. Therefore a conventionalcommunications device must be able to receive the entire bandwidth ofthe sub-frame in order to receive and decode the control region.

Example Up-Link Configuration

PUSCH Structure

According to an example embodiment the up-link of a wireless accessinterface which operates in accordance with LTE is under the control ofthe eNodeB, which receives buffer status reports (BSR) from UEs to aidscheduling decisions. As with the down-link, the up-link includes acommunications channel which provides shared resource known as aphysical up-link shared channel (PUSCH) providing resources, which aregranted in downlink control information (DCI) messages sent on PDCCH.Communications resources are granted to UEs on a resource block group(RBG) basis, where an RBG can contain two, three or five RBs. The grantof PUSCH resources are in contiguous frequency resources to allowtransmission with a low cubic metric since this improves power amplifierefficiency. The exception to this is that, from LTE Rel-10, PUSCH may begranted in two separate ‘clusters’, with each cluster being individuallyin contiguous frequency resources. More details can be found relevant3GPP specifications, for example TS 36.211, TS 36.212, TS 36.213 and TS36.331.

The eNodeB can sound the uplink channel by configuring the UE to send asounding reference signal (SRS), described below. If the bandwidth andquality of the SRS are sufficient, the eNodeB can usefrequency-selective scheduling for PUSCH where the same resource blocksare typically used in both slots of a sub-frame. This is rational sincethe eNodeB has good knowledge of which resources are best for the UEacross a wide bandwidth. Alternatively, if the SRS quality is not goodenough (or no SRS are configured), then LTE supports frequency-diversescheduling (also known as frequency non-selective scheduling). In thiscase, two frequency-hopping options are available to automaticallyexploit the frequency diversity of the channel:

-   -   Inter-sub-frame hopping where the resource allocation frequency        hops between the re-transmissions of a HARQ process. This gives        frequency diversity among the re-transmissions.    -   Intra- and inter-sub-frame hopping where the resource allocation        frequency hops at the slot boundary and also between the        re-transmissions of a HARQ process. This gives frequency        diversity within a single transmission of a transport block as        well as between the re-transmissions.

The hopping mode which is used is broadcast within the cell. In bothcases, the hopping can be in a pre-determined pseudo-random patternconfigured by the radio resource control (RRC) or via an explicithopping offset signalled along with the Up-link resource grant on PDCCH.

FIG. 4 provides an example representation of an uplink frame structure.As shown in FIG. 4, each frame of the uplink is comprised of 10sub-frames in correspondence with the downlink Each of these sub-framesis comprised of two time slots 401, 402. Each slot is comprised of sevensymbols in the time domain, and in the frequency domain each of thesymbols provides a plurality of subcarriers which are assigned to thesame UE. The resource blocks are assigned in the frequency domain on thebasis of 12 subcarriers so that a UE may be assigned N×12 subcarriers inthe frequency domain. Typically, in accordance with a conventionaloperation, a UE is assigned all of the seven symbols in the time slot401, 402. As shown in FIG. 4, two examples 404, 406 represent thesymbols in each slot which include the PUSCH 408 which, as explainedabove provides shared physical channel for uplink resources and amodulation reference symbol (DM-RS) 410. Each of the symbols in the timeslot includes a cyclic-prefix CP 412 which in correspondence with theprinciples of OFDM operation provides a repetition of the samples fromthe wanted channel in a guard period in order to allow for inter-symbolinterference.

DM-RS for PUSCH

The demodulation of reference symbols (DM-RS) 410 for the PUSCH aretransmitted only in RBs for which the PUSCH has been granted. They occurin every time slot 401, 402 and for normal cyclic prefix operation,DM-RS occupy the fourth SC-FDMA symbol as shown in the first examplerepresentation 404 while for extended cyclic prefix operation, as shownin the second example 406 they occupy the third SC-FDMA symbol, asillustrated in FIG. 4.

The sequence length for DM-RS is equal to the number of subcarriersallocated to PUSCH for this UE, and 12 cyclic time shifts are supportedon a DM-RS SC-FDMA symbol to allow orthogonal multiplexing for e.g.multi-user MIMO. If a multi-clustered PUSCH is in use, a sequence of thelength of the total number of allocated subcarriers is generated, and issplit between the two clusters for transmission.

FIG. 5 provides a representation of the structure of a sub-frame for theuplink in the frequency domain. As indicated above each sub-frame iscomprised of two time slots 401, 402 within which there is transmittedseven symbols in the time domain and in the frequency domain each symbolis comprised of sub-carriers allocated to the same UE on the basis ofN×12 subcarriers. However FIG. 5 is a simplified presentation of theup-link which does not shown the transmission of individual symbols, butshows an example implementation of an uplink control channel which forthe example of LTE would be the physical uplink control channel (PUCCH).

PUCCH Structure

As shown in FIG. 5 resource blocks which are allocated to a UE from theshared physical channel PUSCH occupy a central portion of the frequencyband 420 whereas the PUCCH is formed at the edges of the frequency band422, 424. A PUCCH region is therefore two RBs, one in each slot of asub-frame, which are positioned close to opposite ends of the systembandwidth. Precisely which RBs a PUCCH is allocated depends on theuplink control information (UCI) it is carrying (the so-called ‘format’of the PUCCH) and on how many RBs the eNodeB allocates in total forPUCCH in a sub-frame Unlike the PUSCH and the PDSCH, for the exampleimplementation of LTE, the resources for PUCCH are not signalledexplicitly on PDCCH, but are instead signalled by RRC configurationcombined, in some cases, with implicit information relating to thelocation of PDCCH. The RRC configuration itself is partly cell-specificand partly UE-specific, which parts depending on the format.

For the example of LTE networks, in Rel-8 and Rel-9, a UE never hasPUSCH and PUCCH in the same sub-frame to preserve the low cubic-metricof the transmission. Therefore, when UCI is to be transmitted in asub-frame where the UE is to have PUSCH, the UCI is multiplexed ontoPUSCH and PUCCH is not sent. From Rel-10, simultaneous PUSCH and PUCCHcan be configured.

As shown in FIG. 5, the PUCCH is comprised of different formats. ThePUCCH formats convey UCI as follows:

-   -   Format 1: Scheduling Request (SR)    -   Format 1a: 1-bit HARQ ACK/NACK with or without SR    -   Format 1b: 2-bit HARQ ACK/NACK with or without SR    -   Format 2: CSI in 20 coded bits (with 1- or 2-bit HARQ ACK/NACK        in extended CP)    -   Format 2a: CSI and 1-bit HARQ ACK/NACK    -   Format 2b: CSI and 2-bit HARQ ACK/NACK    -   Format 3: Multiple ACK/NACKs for carrier aggregation with        optional SR

The order in which the various PUCCH formats are mapped to RBs in asub-frame with multiple PUCCH formats is shown in FIG. 5, with 2/2a/2bat the band edge, followed by a mixed-format PUCCH (if present) and then1/1a/1b. The number of PUCCH regions available for 2/2a/2b is broadcastin the cell.

The Format 3 is configured from among the PUCCH regions which may beallocated to format 2. The eNodeB scheduler ensures that the regionsoccupied by PUCCH formats 2/2a/2b and 3 do not overlap.

DM-RS for PUCCH

The DM-RS are transmitted separately for the PUCCH and PUSCH. As for thePUSCH, they are transmitted only in RBs for which a UE has PUCCHconfigured, and they occur in every such slot. DM-RS occupy differentSC-FDMA symbols depending on the PUCCH format. An example of such anarrangement is shown in FIG. 6, in which the transmission of format1/1a/1b and its DM-RS for normal cyclic prefix operation is presented.As shown in FIG. 6 for example the PUCCH is arranged to transmit anACK/NACK symbol to the eNodeB which is a typical example of controlinformation transmitted by the UE on the PUCCH. The ACK/NACK symbol 450is multiplied by a receiver spreading code r0 of length-12 by amultiplier 452 before the signal is fed to each of seven cyclic-prefixformers 454. The cyclic-shifters 454 serve to shift the samples of theACK/NACK symbol using a Zadoff-Chu sequence. Each of the signals fromthe cyclic-shifters 454 are received by a multiplier 456 and multipliedby a coefficient of a Walsh-Hadamard sequence in order to spread thespectrum of the ACK/NACK symbol 450 within the time-slot 401, 402. Theoutputs from the multipliers 456 are fed to an inverse Fouriertransformer (IFFT) 458 which convert the sub-carriers which are formedin the frequency domain for the symbol into the time domain andtransmitted as a symbol of the PUCCH within the timeslot 401, 402. Asshown in FIG. 6 the timeslot 401, 402 comprises four PUCCH symbols, twoeach at either end of the time-slot 460, 462 and a central portion 464provides three DM-RS symbols. Therefore for this example, there arethree symbols carrying DM-RS, and the time slot carrying the singleACK/NACK symbol 450 is repeated with cyclic time-shifts and aWalsh-Hadamard code on the remaining SC-FDMA symbols. The UE istherefore able to code division multiplex the transmission of theACK/NACK symbol 450 using the cyclic shifts and Walsh-Hadamard codes.Therefore each UE sending PUCCH format 1/1a/1b in the same PUCCH regionuses a different combination of Walsh-Hadamard code and cyclic shifts ofa base Zadoff-Chu sequence.

A further example of the PUCCH in format 2 is shown in FIG. 7. FIG. 7provides an example in which channel state information (CSI) is afurther example of control information which is transmitted in thePUCCH. The CSI comprises ten coded bits 480, which are fed to a QPSKmodulator 482, which serves to form the ten coded CSI bits into fiveQPSK symbols. Thus format 2 uses QPSK modulation which carry two bitsper modulation symbol. The QPSK modulator 482 forms five QPSK symbolsd0, d1, d2, d3 and d4 for transmission on five PUCCH symbols 490, 492,494, 496, 498. Each of the five QPSK symbols are fed to a multiplier 484which multiplies each of the five QPSK symbols by a length 12 spreadingcode, such as the Walsh-Hadamard sequence as for the above example. Theoutput from multipliers 484 are fed to a cyclic-shifter and an inverseFourier transformer (IFFT) 486, which serve to cyclically shift thespread spectrum QPSK symbols by a cyclic shift code and form the SC-FDMAsymbols in the time domain by performing an inverse Fourier transform.Thus each of the five PUCCH symbols 490, 492, 494, 496, 498 are formedinto the time domain and transmitted with two DM-RS symbols 499, 500. Asshown in FIG. 7, three of the PUCCH symbols form a central part of thetimeslot 401 and two are transmitted at each end of the timeslot withthe DM-RS symbols 499, 500 interposed between the three semper centralPUCCH symbols and the two edge PUCCH symbols.

For the example transmission of format 2/2a/2b illustrated in FIG. 7, itis necessary to carry more control information (UCI data), so there arefewer RS and the coded CSI is QPSK modulated before being spreadsymbol-wise onto the remaining SC-FDMA symbols. Therefore a UEmultiplexes the control information with other UEs in format 2 using thecyclic shifts, in which each UE sending PUCCH format 2/2a/2b in the samePUCCH region uses a different set of cyclic shifts of a base Zadoff-Chusequence.

For the further example of Format 3, which is used to transmit controlinformation, this format provides for transmitting the same time-domainpattern as format 2/2a/2b. The baseband processing is a hybrid offormats 1 and 2 with the addition of phase shifts on the repetitions,and it is not based on Zadoff-Chu sequences. It is not set out in detailhere since it is not used in the example embodiments of the invention.

SRS Structure

The sounding reference signal (SRS) can be configured by the eNodeB toallow sounding of the Up-link channel in order to facilitate, e.g.,frequency-selective scheduling. SRS can be configured across anybandwidth, but since a UE is typically power limited, it may be thatonly a limited bandwidth can be sounded with sufficient quality in onetransmission. The full details of SRS configuration are not described indetail here. However the salient points are:

-   -   SRS are always transmitted in the final SC-FDMA symbol of a        sub-frame in which a UE is configured to send them.    -   SRS can be configured on a periodic basis, or they can be        triggered by eNodeB.    -   There is a cell-specific RRC configuration amounting to telling        all UEs the sub-frames in which periodic SRS may occur from any        UE in the cell. No UE sends PUSCH or PUCCH in the relevant        SC-FDMA symbols.    -   There is a UE-specific RRC configuration of the periodic        sub-frame pattern the UE shall send SRS according to, as well as        other relevant items such as their bandwidth, frequency-domain        position and a hopping configuration.

According to the example embodiment of LTE, the PUSCH/PUCCH and SRS arenever transmitted simultaneously. The PUCCH format 2/2a/2b takespriority over a simultaneously-configured SRS transmission. The PUCCHformat 1a/1b can be configured to take priority oversimultaneously-configured SRS, or its transmission can be shortened byone SC-FDMA symbol with consequential alterations to the PUCCHconstruction. The PUSCH is rate-matched around the RBs containing SRS.

Energy Storage in Terminal Devices

Today, wireless terminals without a fixed power supply store theirenergy in a battery/ies. Batteries are good for energy storage, becausethey are slow to discharge, typically being designed to supply areasonably constant current for a long period. They cannot usuallyprovide sudden bursts of current. But to drive a power amplifier (PA) tohigh power outputs, such a burst of current is needed nevertheless.Simple battery storage is therefore not ideal when better performance ofa terminal could be obtained by transmitting with a much shorterduration than usual at correspondingly higher power density. To allowthe wireless terminal transmitter to provide a burst of power, acapacitor, or capacitor-like technique, can be inserted between thebattery and the power amplifier. Such a capacitor, or capacitor-liketechnique, can have a charge/discharge characteristic which iscontrollable and amenable to rapidly releasing a large proportion of itsenergy (at high current), before recharging from the battery.

Many wireless terminals are battery powered. This can be true whetherthey are mobile, such as smartphones, or reduced capability terminalssuch as for example mobile or fixed reduced capability devices such assmart meters. The intensive signal processing and potentially hightransmit powers required to operate these devices in accordance withmodern wireless standards such as LTE can result in a short batterylife. For smartphones and similar devices, this can mean that frequentre-charge cycles are needed which can limit the appeal to the end useror limit the extent to which the capabilities of the device can be fullyexploited. For some smart meters and similar devices, such as thoseconducting machine-type communications (MTC), battery life mayapproximately equate to device life, because it has been proposed thatMTC devices are to be installed in inaccessible locations and it can beexpensive for a utility company, for example, which owns the meter toreplace the device or its battery.

These problems can be alleviated by technical improvements that reduceterminal transmission power consumption at the physical layer and, amongsuch improvements, those with a small impact on data rate are ofparticular interest. One of the simplest methods to reduce powerconsumption is merely to turn off the terminal's transmit hardware for agreater proportion of the time. But this is not desirable in general,since it will reduce the ability of the terminal to communicate. Afurther problem, of particular pertinence to the smart-meter MTCterminal scenario is coverage. MTC devices may be installed in placessuch as deep residential basements from where it is hard forconventional LTE radio transmissions to reliably reach the eNodeB. Thiscan result in high transmit power and/or re-transmissions to reachrequired performance levels, both of which are disadvantageous tobattery life. Therefore, in such cases, it is desirable instead ofreducing total transmit power, to keep the transmission power constantand concentrated into a shorter transmission duration, resulting in ahigher received power-density at the eNodeB which can translate intohigher reliability on the uplink.

Flashbulb Principle

According to the present technique a UE is restricted to only a few tensof microseconds of transmission per sub-frame, which is referred to inthe following description as a ‘flashbulb’ transmission, but the precisetemporal location and duration of transmission can be controlled by acontroller controlling the UE transmitter. A particularly relevant wayof enabling this kind of transmission is to store energy, which isaccumulated by a UE's transmitter from a power source or a battery overa period of time and to release the energy in a burst, rather as if thepower source charges a capacitor which is discharged quickly as has beenexplained above. According to the present technique an amount of timefor which a terminal is required to transmit to send a certain number ofbits is reduced, resulting in a more efficient use of radio resource andpower efficient operation of the uplink According to some embodimentsfor the example application to LTE, the transmission of the controlinformation on an uplink control channel such as the PUCCH is used toconvey further information or form part of the control information. Thiscan be achieved for example by the steps that (i) the SC-FDMA symbol atwhich the transmission begins; and/or (ii) the location of referencesignal(s) transmissions within the overall transmission and (iii) whichof a predefined set of possible reference symbol sequences is used bythe UE are used at the eNodeB as additional states to interpret themodulated symbols contained in REs covered by the transmission. It isassumed that, since the decoding of the Up-link occurs at the eNodeB,processing power and time is not a significant constraint.

Example embodiments of the present technique will now be described withreference to the example of an LTE network with application to the PUCCHand PUSCH and their respective associated DM-RS. According to someexample embodiments one or more of the following aspects maycharacterise the operation of a communications device (UE):

-   -   Transmission from a flashbulb-capable UE is always in contiguous        SC-FDMA symbols.    -   A UE transmitter can be controlled to position a burst of        transmission accurately to begin in any SC-FDMA symbol of a        given sub-frame and further to control the duration of the burst        of transmission to as little as one SC-FDMA symbol.    -   Transmission should preserve the single-carrier nature of the        LTE Up-link as per Rel-11.    -   Existing Up-link physical channels and signals should all be        supported to some degree, but can be re-designed where needed.        Transmission of Flashbulb UE in PUCCH

As explained above, embodiments of the present technique can provide anarrangement in which a UE can reduce its power consumption by reducingits transmission time for transmitting a predetermined message in afirst time period which is shorter than a second time period, which hasbeen allocated for the transmission of that information by aconventional UE. A system which has been configured to transmit specificinformation in the second time period, whereas according to the presenttechnique the UE is adapted to transmit the information in a shorterfirst time period, which is less than the second allocated time period.A communications device (UE) operating in this way is referred to as a‘flashbulb UE’. One example application will now be described withreference to the transmission of control information by a Flashbulb UEin the PUCCH of an LTE based wireless access interface. As explainedabove with reference to FIG. 5, the PUCCH is one physical resource block(PRB) wide in each slot of a sub frame, and positioned at opposite edgesof the bandwidth 422, 424 in the two slots 401, 402. The precisearrangement of data and DM-RS onto the SC-FDMA symbols of a PRB variesbetween the PUCCH formats as explained above.

In one example embodiment, the UE is given a configuration by the eNodeBthat it can send control information on the PUCCH of a given durationwithin a time-domain resource that is longer than the configuredduration, thus giving the UE the choice of where to position itstransmission. That is to say that the transmission time of the signalsrepresenting the control information is shorter than the temporal lengthof the PUCCH provided by the wireless access interface, and thereforethe Flashbulb UE has a choice of where to position the transmission. Theposition in the time domain serves to convey further information to theeNodeB or conveys part of the control information and in one form can beto index a higher-order modulation scheme based on the lower-order datacarried on the SC-FDMA symbols themselves.

One example illustration is shown in FIGS. 8a and 8b . FIGS. 8a and 8bprovide an illustration of the resource elements which form the resourceblocks of the PUCCH within a sub-frame. As explained above, thesub-frame comprises two time-slots 401, 402. As shown in FIGS. 8a and 8bthe example of the PUCCH shown provides seven OFDM symbols per time slot401, 402, which are number 0 to 6. Each symbol comprises a block of 12OFDM sub-carriers in the frequency domain. This corresponds to aconventional arrangement explained above with reference to FIGS. 5, 6and 7. A conventional UE would transmit control information in all ofthe seven symbols and the 12 sub-carriers of the timeslot and in bothtimeslots 401, 402, as explained above. According to present techniquehowever a flashbulb UE is configured to transmit on only three of theseven OFDM symbols across the OFDM subcarriers and furthermore the threesymbols whilst being contiguous in time can vary in position thusconveying further information to the eNodeB. In some examplestransmission only occurs in one of the timeslots and not the other. Thusas shown in FIG. 8a the control information is transmitted only onsymbols numbered 4, 5 and 6 in FIG. 8a and symbols numbered 5, 6 and 7in FIG. 8b . Accordingly, the position of the transmission by theflashbulb UE conveys further information, which may form part of thecontrol information as explained below. Therefore the exampleillustration shown in FIGS. 8a and 8b which illustrates a PUCCHcomprising of a single resource block the Flashbulb UE has the followingconfiguration:

-   -   Width of transmission=3 symbols    -   Transmission to be confined within symbols numbered 3 to 6        inclusive    -   DM-RS for PUCCH to occupy one symbol

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is based on PCT filing PCT/EP2014/065310 filedJul. 16, 2014, and claims priority to European Patent Application 13 180489.0, filed in the European Patent Office on Aug. 14, 2013, the entirecontents of each of which being incorporated herein by reference.

Thus as shown in FIGS. 8a and 8b , the UE can transmit a pair of datasymbols in SC-FDMA symbols (3, 4, 5) or (4, 5, 6), which in one examplecan be interpreted as different information sets, which are called ‘Set1’ and ‘Set 2’ respectively. Then the position-based modulation optionsare as depicted in Table 1 below, where a BPSK-based example has beenused for simplicity of presentation but without loss of generality. Thisparticular flashbulb arrangement is most relevant to PUCCH format2/2a/2b which would use QPSK pairs instead of the BPSK pairs we haveused here for clarity. So by way of example, in FIG. 8a , an eNodeBdetecting nothing in SC-FDMA symbol 3, ‘0’ in SC-FDMA symbol 4 and ‘1’in SC-FDMA symbol 6 concludes that the actual information data beingconveyed is ‘101’. Upon detecting the transmission in FIG. 8b , theeNodeB concludes that the actual information data being conveyed is‘001’.

TABLE 1 Binary pair 0, 0 0, 1 1, 0 1, 1 Set 1 000 001 010 011 groupedsymbol Set 2 100 101 110 111 grouped symbol

An example of a UE operating in accordance with the present technique isshown in FIG. 9. In FIG. 9 a flashbulb UE 501 includes a transceiverunit 502 and a controller 504. A transceiver unit 52 contains atransmitter and receiver adapted to transmit and receive signals via thewireless access interface provided by the mobile communications network.The controller controls the transceiver to transmit and receive the datawhich is then fed to or received from a higher layer application whichis not shown. However what is relevant to the illustration of thepresent technique is the operation of a controller which is presented inthe form of a flow diagram as operation steps within the controller 504within a bubble 506. As shown in FIG. 5 binary data which isrepresenting the control information is generated as a first step 508which is then fed to a bit to symbol grouping 510 in order to transmitthe binary data on the modulation symbols which have been adapted torepresent the control information in accordance with the presenttechnique. The modulation symbols are then received at a flashbulbmapping step 510 which is configured to map the modulation symbols ontothe frequency division multiplexed symbols and subcarriers of the PUCCHchannel in accordance with the information to be conveyed. The mappingof the modulation symbols onto the selected frequency divisionmultiplexed sub carriers is determined in accordance with a tableproviding the allowable mapping of the frequency division multiplexedsymbols and providing an indication of the information which thatconveys. For example a data store 514 provides a representation of themapping information identified in table 1. Accordingly the flashbulbmapping step 512 generates an indication of a binary pair on an output516 and the frequency division multiplexed symbol set 518 which are fedto the transceiver unit 502 on corresponding outputs 516, 518 as shownwithin the flashbulb UE 501. Therefore as illustrated in FIG. 9 a binarydata stream is grouped into sets of ‘grouped’ symbols of the relevantsize by step 510. For example 3 bits (similar to 8-PSK) in Table 1, areused to determine whether ‘ Set 1’ or ‘Set 2’ of the SC-FDMA symbolsshould be used, and which binary pair should be transmitted as output atstep 516 and the two data-carrying symbols of step 518.

As a result of the arrangement shown in FIG. 9, three bits can betransmitted by signalling only two, equivalent to transmitting an 8-PSKsignal using BPSK. However, three SC-FDMA symbols have been used for thepurpose and four symbols are reserved although the fourth symbol uses notransmit power. Accordingly in comparison to a conventional UE, fewerSC-FDMA symbols and therefore less transmit power is used, than wouldconventionally have been needed since, to transmit a hypothetical three‘grouped’ symbols in current PUCCH 2/2a/2b structures would require atleast four symbols including DM-RS.

More symbol sets could be created to increase the number of states thatcan be transmitted. For example the next power of two would require aset of five symbols to be reserved for this example transmission, sothat there are four possible sets of contiguous symbols to choose from.

The mapping in Table 1 would have a bit error rate (BER) resulting frompotentially incorrect detection at the eNodeB of the received controlinformation. Gray coding is a known technique for minimising a bit errorrate by positioning modulated symbols with bit changes close together.According to one example a Gray code mapping of the information fromTable 1 could be as shown below in table 2, where only one bit in agroup of bits which forms a modulated symbol changes between adjacentbinary pairs within a set and only one bit in a modulated symbol changesbetween each symbol set within a binary pair.

TABLE 2 A Gray mapping relevant to Table 1. Binary pair 0, 0 0, 1 1, 11, 0 Set 1 000 001 011 010 grouped symbol Set 2 100 101 111 110 groupedsymbolVary Position of DM-RS

In another example embodiment the controller 504 of the Flashbulb UE isarranged to vary the position of the DM-RS symbol as part of thetransmission provided that three symbols are still time-contiguous. Inthe example, in which one DM-RS is transmitted as any of the threesymbols contained wholly within either of ‘Set 1’ or ‘Set 2’, accordingto which set has been chosen for data transmission, a total of twentyfour states can be transmitted using two binary bits. Since twenty fouris not an integer power of two, it may be sufficient to define only twopermissible positions for the DM-RS symbol within each set of SC-FDMAsymbols, resulting in sixteen states equivalent to four bits. This isillustrated in FIGS. 10a and 10b where the BPSK pair of modulationsymbols are being transmitted, which are represented as 0, 1 andcorresponds to the example configuration of FIGS. 8a and 8b . Thus FIGS.10a and 10b provide a representation of the transmission of BPSK symbolswithin a first timeslot 140 of a sub-frame. In contrast to the exampleshown in FIGS. 8a and 8b , the uplink transmission of DM-RS symbolvaries from a first position 552 in FIG. 10a to a second position of 552in FIG. 10b . For the example shown in FIGS. 10a and 10b , themodulation symbols both indicate the same value of 0 and 1. However bychanging the position of the DM-RS symbol additional information can besignalled.

Thus as illustrated in FIGS. 10a and 10b the first and second modulationsymbols transmitted are 0 and 1. A mapping of the combination of SC-FDMAsymbol set and DM-RS positions from binary pair to quaternary symbols isshown in Table 3. This table could also be Gray mapped in various waysfollowing the example of Table 2. Table 3 below provides an indicationof the possible signalling information being transmitted on a controlchannel. The eNodeB then detects whether the DM-RS symbol is in position‘A’, that is shown in FIG. 10a or in a position ‘B’ that is shown inFIG. 10b . If the transmitted DM-RS symbol is in position ‘A’, then thesecond column indicates that the control information could be either‘0001’ or ‘0101’ depending on whether the frequency division multiplexedsymbols were transmitted as set one or set two. For the examples shownin FIGS. 10a and 10b the signals were transmitted in frequency divisionmultiplexed symbols 4, 5 and 6 and therefore correspond to set two.Accordingly, FIG. 10a represents a transmission of signallinginformation ‘0101’ whereas the transmitted signals represented in FIG.10b represents signalling information ‘1101’. As can be appreciatedtherefore by changing the position of the DM-RS reference symbols,further information can be signalled without requiring any increase inthe modulation level or transmission of more frequency divisionmultiplexed symbols thereby shortening the transmission by the FlashbulbUE.

It could be preferable in cases where not all possible DM-RS locationsare permitted, such as in this example, to separate the permittedpositions as widely as possible in time in order to reduce mis-detectionprobability among DM-RS symbol positions, which is illustrated in FIGS.10a and 10b .

TABLE 3 DM-RS in position ‘A’ DM-RS in position ‘B’ Binary pair 0, 0 0,1 1, 0 1, 1 0, 0 0, 1 1, 0 1, 1 Set 1 grouped 0000 0001 0010 0011 10001001 1010 1011 symbol Set 2 grouped 0100 0101 0110 0111 1100 1101 11101111 symbol

A further increase to the efficiency of transmission of controlinformation can be achieved by using more than one sequence forgenerating the DM-RS. If either of two possible sequences can be used,then following the sixteen-state example presented above on FIG. 3 canbe used to create thirty two signalling states, which is equivalent to 5bits.

An example of a reduction in power consumption resulting which can beachieved using the above described embodiments can be considered using aPUCCH format 2/2a/2b, where, within one slot, five QPSK symbols and twoDM-RS symbols are sent, requiring seven SC-FDMA symbols in total. In theexample given above, by replacing the BPSK pairs with QPSK pairs, onlythree SC-FDMA symbols are required thus reducing the power consumed byapproximately 57%. An alternative embodiment provides an arrangement inwhich the Flashbulb UE does not reduce its total transmission powerconsumption but instead concentrates its power into the much-reducedtime duration of the transmission, so increasing the power density withwhich it will be received by the eNodeB, thereby improving the Up-linkcoverage in the cell. Any mixture of the two is clearly also beneficialcompared to known methods.

Use of Physical Resource Blocks (PRB)

In the example embodiments presented above, the transmission of thesignals carrying the control information is within the first time slot401 of the sub-frame. However the transmission could equally be arrangedin the second time slot 402. Furthermore a conventional operationprovides a UE with PUCCH resource at opposite band edges in the twoslots 401, 402 of a sub-frame. In accordance with some exampleembodiments the Flashbulb UE is required to transmit signalsrepresenting the control information across different frequency bands inthe first and second time slots 401, 402. However the break intransmission would imply that the UE used symbols not contiguous withthe end of the first slot, for example as shown in FIG. 8a . This wouldviolate the time-domain contiguousness requirement. Therefore, in someembodiments the physical resource block (PRB) at the opposite band edgein the second slot 402 is granted to a second ‘Flashbulb’ UE which wouldbe configured similarly to, but independently of, the first UE in thefirst time slot 401. Similarly, the second PRB in the first time slot401 could be granted to a third Flashbulb UE, and the second PRB in thesecond time slot 402 to a fourth Flashbulb UE. This would be a differentscheduling arrangement than that depicted for current PUCCH in FIG. 5.Therefore in some embodiments the resources provided by the PUCCH can beused by more than one Flashbulb UE, so that the resources are morecompletely utilised.

In an alternative example embodiment, in order to maintain some of thefrequency diversity of the existing PUCCH design for at least one UE,the UE can be granted resources in contiguous SC-FDMA symbols but splitacross the two time slots and across the two band edges at the slotboundary. This is illustrated in FIG. 11. In FIG. 11, the transmissionof flashbulb UE extends across the first timeslot 401 and the second istimeslot 402. As illustrated in FIG. 11 the transmission occurs infrequency division multiplexed symbols numbered 4 to 9. In accordancewith this example the transmission is split across the first frequencyband 560 and a second frequency band 562 which in accordance with theexample illustrated in FIG. 5 is split at either edge of the allocatedup-link frequency band. As shown in FIG. 11 three of the frequencydivision multiplexed symbols 570, 572, 574 are allocated fortransmitting frequency division modulation symbols whereas symbolsnumbered 5 and 8 are allocated for transmitting DM-RS symbols 576, 578.For the example illustrated in FIG. 11 the flashbulb UE would beconfigured as follows:

-   -   Width of transmission=5 symbols    -   Transmission to be confined within symbols numbered 4 to 9        inclusive    -   DM-RS for PUCCH to occupy one symbol in each slot were PUCCH is        sent

To show the extent of this case, the transmission is shown as containingthree data symbols and two DM-RS symbols. The UE is allowed to vary thedistribution of the PUCCH transmission between the two slots: in thisparticular example it has a reservation of three symbols in each slot.DM-RS will be needed in each slot since the transmissions in the twoslots are widely separated in the frequency domain. In general, a UEmight not use any of its granted resources in one of the slots.

As will be appreciated a combination of the example embodimentillustrated in FIG. 11 can be combined with the other exampleembodiments disclosed in FIGS. 8 to 10.

PUCCH Format 1a and 1b

In PUCCH format 1a and 1b, one or two information bits carrying ACK/NACKare sent respectively in BPSK or QPSK modulated symbols. In existingLTE, the ACK/NACK bit is sent on (up to) four SC-FDMA symbols per slotusing what amounts to repetition coding, with DM-RS on the remainingthree SC-FDMA symbols. This generally results in a lower signal to noiseratio operating point than for format 2/2a/2b.

According to example embodiments some of the possible states of thesignal transmission can be created to be assigned to ACK and some statesto NACK. This means that even in the presence of incorrectly determiningthe transmitted state, the information bit is still decoded correctly.The principle of Gray coding could again be useful here so thatlogically adjacent states map to the same information bit. In theexample of Table 2, one possible Gray code mapping is shown, realised onthe assumption that the most common error is within a binary pair beingmis-detected in the wrong frequency division multiplexed (SC-FDMA)symbol set, which for ACK/NACK is presented in table 4.

TABLE 4 Binary pair 0, 0 0, 1 1, 1 1, 0 Set 1 ACK ACK NACK NACK groupedsymbol Set 2 ACK ACK NACK NACK grouped symbol

A Gray code mapping realised on the basis that the most common error iswithin a frequency division multiplexed (SC-FDMA) symbol set where thebinary pair is mis-detected could be as shown in table 5:

TABLE 5 Binary pair 0, 0 0, 1 1, 1 1, 0 Set 1 ACK ACK ACK ACK groupedsymbol Set 2 NACK NACK NACK NACK grouped symbol

Similar mappings can be developed for the method also using DM-RS timingillustrated by FIGS. 10a and 10b and Table 3. This example is for PUCCHformat 1a; QPSK pairs would be used for format 1b. An advantage isprovided for this embodiment whereby transmission is robust to decodingerrors at the eNodeB but still uses less transmission power than theconventional LTE scheme, as it uses only three SC-FDMA symbols ratherthan the seven in a timeslot (or fourteen in a sub-frame).

UE Time Multiplexing

As explained above, according to some example embodiments, the resourcesof the PUCCH which are not used by a flashbulb UE are allocated toanother flashbulb UE so that the available resources can be timemultiplexed between a plurality of UEs. Clearly as shown in the aboveexamples, not all resource elements in the PRB illustrated above arebeing used. The unused resource elements could be assigned to one ormore other UEs, who would have a correspondingly different configurationto the Flashbulb UE used in the example. Continuing the above example,within the one PRB, a second UE would be able to have three-symbolsreserved in SC-FDMA symbols (0, 1, 2), within which one possibleconfiguration is to transmit one data symbol and one DM-RS symbol (i.e.two SC-FDMA symbols in total) time-contiguously and the other exampleembodiments as explained above. This UE would have a lower Up-link datarate than the first UE if both operated otherwise identically.

Therefore as will be appreciated from the above discussion, embodimentsof the present technique can provide an arrangement in which a pluralityof flashbulb UEs are multiplexed within a one PRB. In contrast in otherembodiments flashbulb transmissions could be multiplexed from aplurality of UEs in a number of different PRBs.

Since PUCCH allows code multiplexing of UEs in the same resourceelements, in some embodiments UEs can be given overlapping flashbulbreservations and these reservations can overlap in all, or only some, oftheir SC-FDMA symbols.

Transmission of Flashbulb UE in PUSCH

On conventional PUSCH, one modulated symbol is sent independently oneach resource element of a granted PRB. This arrangement contrasts withthe PUCCH where one modulated symbol is sent with frequency spreadingacross all 12 resource elements in a SC-FDMA symbol. Even with thisconstraint, in some embodiments a mobile communications network can bearranged to provide a facility for transmitting data on the sharedchannel of the wireless access interface, which for LTE is the PUSCH,whilst conforming to the flashbulb transmission principles. In thisexample, data is transmitted by a UE in a smaller number of frequencydivision multiplexed symbols than are provided in each time slot of aPUSCH. However in contrast to the transmissions on PUSCH in knownsystems, the transmission on the PUSCH according to the invention aresuch that the REs are no longer independent over the time domain.

An example illustration is shown in FIG. 12. In FIG. 12 which reflectsthe up-link frame structure shown in FIG. 5, two timeslots are shown401, 402 of the up-link sub-frame which have been allocated fortransmission to a UE. However in accordance with the present techniqueif the UE is a reduced capability UE or operating as a Flashbulb UE thenas will be explained below the eNodeB has been adapted to allow the UEto transmit data in a smaller number of the frequency divisionmultiplexed (SC-FDMA) symbols in each of the time slots in order toreduce a transmission time and therefore power consumed in accordancewith the flashbulb UE principles outlined above. Thus as shown in FIG.12 the hashed symbols 600, which are numbered 3, 4 and 5 of the sevensymbols of the first time slot 401 represents a transmission of theflashbulb UE 600 whereas in the second time slot the symbols number 4, 5and 6 of the seven available SC-FDMA symbols are used to transmit thedata 601 by the Flashbulb UE.

As will be appreciated all of the embodiments of the present techniquewhich have been described with reference to the PUCCH explained abovecan be applied to the PUSCH. Accordingly as indicated by an arrow 602,604 the position of the transmissions in the reduced number of SC-FDMAsymbols can vary in position in order to provide additional informationor to convey part of the data which is transmitted to the eNodeB by theFlashbulb UE.

As indicated above in order for the mobile communications network toallow a UE to perform the Flashbulb technique in which only some of theseven symbols of a time slot of the sub-frame are used then the eNodeBneeds to be configured to receive the data transmitted on a smallernumber of SC-FDMA symbols. FIGS. 13a, 13b, 13c, and 13c provide exampleembodiments in which a signalling exchange between a reduced capabilityUE and an eNodeB is performed in order to provide an arrangement fortransmitting data in a smaller number of the SC-FDMA symbols which areavailable in a time slot 401, 402. In FIG. 13a the eNodeB 620 transmitsa broadcast message 622 to the UE 624 within the cell indicating thePUCCH transmission format which can be used by a flashbulb type UE totransmit data in a smaller number of SC-FDMA symbols that are availablewithin each slot. In other embodiments eNodeB 620 provides transmissionformats for flashbulb techniques for the PUSCH. Thus in the presentexample of FIG. 13a once the PUCCH/PUSCHtransmission formats forflashbulb UEs have been transmitted in the cell then any UE which isrequested and granted resources on the PUSCH and/or PUCCH will transmitdata in a smaller number of SC-FDMA symbols than are available in eachslot.

In contrast in FIG. 13b a UE 630 transmits as part of a set upprocedure, which establishes a context, an indication that it is areduced capability UE using a message 632. The eNodeB responds byproviding the transmission format indicating the symbols of the timeslotwhich can be used for transmitting data on the shared channel 634. Analternative in FIG. 13c represents an arrangement in which the UE 638transmits a PRACH 640 by which it is indicated that the UE 638 is areduced capability UE. In other words, the UE 638 is indicating that itwishes to use the flashbulb principles in which data is transmitted in asmaller number of SC-FDMA symbols. In response the eNodeB 620 grantsresources on the PUSCH and/or PUCCH and indicates in the resource grant642 that the UE should use a certain number of the SC-FDMA symbols whichis less than the predetermined number of symbols of the timeslot fortransmitting data. Finally in FIG. 13d a UE 640 transmits a conventionalPRACH transmission 646 to the eNodeB 620. In the example shown in FIG.13d the eNodeB 620 and the UE 644 have already established that the UE644 is a flashbulb type UE or reduced capability device and accordinglywhen the grant of resources on the PUSCH and/or PUCCH is transmitted ona message 650 there is indicated the SC-FDMA symbols which the UE shoulduse to transmit data on the PUSCH.

According to examples shown in FIGS. 13a, 13b, 13c, 13d an arrangementis provided for identifying the symbols of each of the timeslots inwhich a UE can transmit data on the shared channel thus implementing theprinciples explained above for the PUCCH on the shared channel PUSCH,although the principles can also be applied to the PUCCH. Using thisarrangement, the UE is given a configuration including a reservation ofa subset of the SC-FDMA symbols within a PRB. Then, separately on eachfrequency-domain subcarrier, the time-contiguous resource elementswithin the PUSCH reservation can be used jointly to transmit a modulatedsymbol in the manner shown in, e.g. Table 2. For this example, there isno particular restriction to BPSK pairs, and any permitted modulationscheme could be used, e.g. 64-QAM. Thus, the UE can transmit any patternof information bits (of a suitable length) on each frequency subcarrier.There could be a reduction in the peak PUSCH data-rate that could beachieved, but according to the example embodiment in which powerconservation is a significant requirement, it may well also be the casethat the UE's typical data rate is low and the peak rate is not ofprimary concern.

In essence, applying the present technique to the PUSCH demonstratesthat there is no particular insistence that the transmission be acrossall subcarriers of an SC-FDMA symbol, in contrast to thefrequency-domain spreading that is used on PUCCH.

PRACH

Of the existing LTE PRACH formats according to Release 11 of 3GPPspecifications, format 4 already fits flashbulb operations, since itsduration is only two SC-FDMA symbols, but it is restricted to use onlyin TDD modes. This format can therefore be used with the example shownin FIGS. 13b and 13c . Existing specifications could be relaxed to allowPRACH format 4 to be used by FDD UEs as well as TDD UEs as long as anFDD UE is operating in flashbulb mode. This would be aided by allowingFDD systems to configure more than one PRACH resource in a PRACHopportunity so that flashbulb and legacy UEs need not interfere in thisrespect. Signalling of this would need to be added in the cell broadcastinformation (currently in SIB2). A UE capable of operation in eitherconventional or flashbulb mode could be left with a choice of the mannerand resources in which it access PRACH, or the cell could furtherbroadcast instructions, or specifications could contain instructions,regarding what such UEs must do. If the UE has the choice, then theeNodeB can use the manner of PRACH access to determine the flashbulbcapability (or, at least, a preference) of a UE, reducing the need forlater RRC message exchanges for the purpose. Other possibilities, wherethe basic principles may be already known to the art, includepredefining certain among the random access preambles as to be selectedamong by UEs wishing to indicate flashbulb operation and the rest forUEs operating conventionally.

Alternatively, a UE could operate in conventional LTE mode duringinitial cell acquisition procedures, including PRACH transmissions, andthen move to, or be configured by eNodeB into, flashbulb operation oncean RRC connection has been established.

Transmission of Sounding Reference Signal (SRS)

In a conventional LTE network, SRS can occupy the final SC-FDMA symbolof a sub-frame, so that the eNodeB can use the channel estimate reliablyin the next sub-frame. The sub-frames and frequency resources in which aUE sends SRS are controlled by the eNodeB, but can extend acrossessentially any bandwidth if the UE has sufficient transmit power. Insub-frames where a UE is sending PUCCH and/or PUSCH, those transmissionsare shortened by one SC-FDMA symbol if SRS are also present. There aretwo cases with respect to Flashbulb operation:

-   -   The UE has only SRS in this sub-frame. The UE effectively        operates in flashbulb mode in conventional systems; or    -   The UE has flashbulb PUCCH and/or PUSCH as well as SRS in this        sub-frame. The time-contiguity requirement of flashbulb        operation is not met in general.

In some example embodiments a flashbulb UEs may have only intermittentdata to transmit and so it may be preferable to rely on a triggered SRS,available from Rel-10 LTE, so that the UE sends SRS at the very end ofone sub-frame and flashbulb PUCCH/PUSCH can then be scheduledefficiently. In a similar way, an eNodeB scheduler behaviour could be toconfigure UEs from which it is expecting SRS in a given sub-frame tohave flashbulb reservations that are contiguous with the final SC-FDMAsymbol of the sub-frame. This would amount to the UE having no choice ofthe SC-FDMA symbols in which they must transmit, but it would still beable to position DM-RS for PUCCH/PUSCH as shown in FIGS. 10a and 10b andTable 3.

In summary existing SRS and flashbulb PUCCH/PUSCH operation can co-existgiven suitable eNodeB scheduling behaviour.

According to the embodiments identified above, a communications device,which may be an MTC type device operating as Flashbulb UE cansignificantly reduce its power consumption because the controller of thetransceiver unit transmits signals representing the data in a subset ofSC-FDMA symbols of a PRB which are available to it. In one example givenabove, power consumption is reduced by 57% without reducing the numberof bits transferred per PRB. Alternatively, the power consumption couldbe maintained but concentrated into the reduced resources occupied byflashbulb operation, thus increasing the Up-link coverage in the cell.This in turn would tend to reduce the need for re-transmissions from UEsas well as the downlink signalling from the eNodeB to trigger andcontrol them. These two advantages can be mutually traded-off againstone another to achieve any mix of power-consumption reduction andcoverage extension that a device manufacturer desires.

If more than one UE is multiplexed into a PRB, then the capacity of thetransmission channel can allow one or more other UEs to have Up-linkresources per sub-frame.

General

eNodeB Decoding

In order to decode a flashbulb transmission, the eNodeB according to oneimplementation would have to search blindly over the possibletransmissions that a UE could have made. This will tend to increase thedecoding time and processing effort at the eNodeB, but significantlygreater amounts of both are available there than at the UE. Amis-decoding at the eNodeB of a flashbulb transmission could trigger thesame procedures as in conventional LTE.

Flashbulb Resource Grants

The resource grants and reservations for flashbulb Up-link transmissionwould need to include the conventional information regarding which PRBsa UE is granted as well as which SC-FDMA symbols it can assume arereserved for it. These reservations could be;

-   -   Included in the grant on PDCCH by expanding the contents of, or        creating new, DCI messages;    -   Configured semi-statically by RRC per UE;    -   Broadcast in the cell as a function of, e.g. UE identity for        those cases where UEs can be multiplexed into the same REs.

Accordingly embodiments of the present technique can be used to requestand receive resource grants in a way which is backwardly compatible withconventional UEs and LTE networks since a non-flashbulb UE can begranted PRBs that are distinct from PRBs assigned to flashbulb UEs.

UE Modes

A given UE might be able to operate in conventional LTE mode as well asflashbulb mode depending on its power consumption requirements at agiven time. Such a UE could signal to the eNodeB that it wishes to moveto/from conventional to flashbulb operation by, e.g.,asserting/releasing a flag at RRC. A simpler UE might only be able toindicate that it can operate in flashbulb mode, but not be able toindicate a wish to change mode. In either case, if the eNodeB decides toput a UE into flashbulb operation, it can indicate as much either in aPDCCH message on a per-sub-frame basis or semi-statically at RRC. Ingeneral, then, a suitably-capable UE might be instructed to move to andfrom flashbulb operation on a per-sub-frame basis or at any time.

MTC Up-Link Transmissions

Depending on the physical implementation of the flashbulb operation of aUE, it may be that there is a delay between individual flashbulbtransmissions. As such, embodiments of the present technique can providean advantage for MTC UEs where Up-link transmissions can tend to besmall and occasional. Although the capacitor-like UE energy storagementioned above provides an example of performing the Flashbulb liketransmission, embodiments of the present technique are not limited tothis method of implementing the Flashbulb transmission and othertechniques are possible.

Example embodiments of the present technique can therefore provide thefollowing advantages:

-   -   A UE receives an Up-link resource reservation, and is not        directed by eNodeB as to which part of it is used for        transmission, whereas at present an Up-link grant is used in its        entirety with rate-matching as necessary.    -   The timing of the start of a transmission conveys part of the        information being sent in the transmission, whereas the UE        presently has no time-domain freedom from the eNodeB        grant/configuration for PUSCH/PUCCH.    -   The timing of the transmission of RS associated with PUSCH/PUCCH        conveys part of the information being sent in the transmission,        whereas this is not the case at present.    -   For PUCCH format 1/1a/1b in particular, the transmission of HARQ        ACK/NACK in any of multiple states provides a robust        transmission without using the existing LTE technique (which is        essentially time-domain repetition).    -   For PUSCH in particular, the joint transmission of data over        several SC-FDMA symbols within one frequency sub-carrier is        different to current operation, where each RE is entirely        independent.    -   For PRACH in particular, a UE capable of both conventional and        flashbulb operation is able to communicate this at an early        stage of operation by its choice of resources for and manner of        PRACH transmission.    -   The eNodeB has a new capability to alter the mode of operation        of a UE between conventional and flashbulb operation according        to any of (i) the UE's capability; (ii) the UE's preference        among its capabilities; (iii) the eNodeB's preference. As a        result, the mode of operation of a UE can be a hybrid of        conventional LTE and flashbulb LTE, in any particular        time-domain pattern per sub-frame.        Example Mobile Communications System

FIG. 14 provides a schematic diagram showing part of an adapted LTEmobile communications system. The system includes an adapted eNode 1401connected to a core network 1408 which communicates data to a pluralityof conventional LTE devices 1402 and reduced capability devices 1403within a coverage area (i.e. cell) 1404. Each of the reduced capabilitydevices 1403 has a transceiver unit 1405 which includes a receiver unitcapable of receiving data across a reduced bandwidth and a transmitterunit capable of transmitting data across a reduced bandwidth whencompared with the capabilities of the transceiver units 1406 included inthe conventional LTE devices 1402.

The adapted eNodeB 1401 is configured to allow the reduced capabilitydevices to transmit signals on the Up-link PUCCH or PUSCH using theFlashbulb techniques described above for example with reference to FIGS.1 to 13. A transmitter and receiver unit 1409 forms a wireless accessinterface under the control of a controller 1411, which also performsthe function of an adapted scheduler. The reduced capability devices1403 are thus able to receive and transmit data using the up-link inaccordance with an operation which can conserve power according to thepresent technique as summarised by the flow diagram for the PUCCH asshown in FIG. 15 and by the flow diagram for the PUSCH as shown in FIG.16. FIG. 15 is summarised as follows:

S1: As with a conventional operation a communications device (UE)transmits and receives data via a wireless access interface provided bya mobile communications network. The wireless access interface includesan uplink control channel for transmitting signalling information inaccordance with a predetermined format in which signals representing thesignalling information occupy a predetermined number of frequencydivision multiplexed (SC-FDMA) symbols of a time period of the controlchannel. The time period may be a sub-frame or a time slot of thesub-frame into which the frame is divided.

S2: The UE adapts the transmission of signals representing thesignalling information in the control channel to occupy a smaller numberof the predetermined number of frequency division multiplexed symbols ofthe time period of the control channel. By reducing the transmissiontime by transmitting signalling information in a smaller number offrequency division multiplexed symbols than are available on the controlchannel then there is a corresponding reduction in power consumption.

S4: An eNodeB of the mobile communications network is adapted to searchthe control channel to detect the signals representing the signallinginformation which has been transmitted in the smaller number offrequency division multiplexed symbols.

S6: Optionally in one example, the UE varies the starting symbol inwhich the reduced number of frequency division multiplexed symbols aretransmitted between one of a plurality of predetermined start symbols.Thus each different starting frequency division multiplexed symbolprovides an indication of further information. In one example, thefurther information forms part of the signalling information which isbeing transmitted.

FIG. 16 provides an example illustration of the operation of anotherexample embodiment where the UE transmits data on a shared channel(PUSCH) of the wireless access interface provided by the mobilecommunications network and a corresponding reduction in powerconsumption is achieved. The operation of a UE is for this exampleembodiment represented in FIG. 16 which are summarised as follows:

S8: A UE transmits and receives data via a wireless access interface inaccordance with a conventional operation. However the wireless accessinterface includes an uplink with a shared channel providingcommunications resources which are shared with other communicationsdevices and comprises in the time domain a predetermined number offrequency division multiplexed symbols in each time period forallocation to communications devices. Again, the time period may be asub-frame or a time slot of the sub-frame into which the frame isdivided.

S10: The UE transmits to the mobile communications network an indicationthat the communications device is a reduced capability device.Alternatively, the UE transmits an indication that it wishes to operateas a flashbulb UE or provide some indication that the UE is to reduce anumber of frequency division multiplexed symbols which are available fortransmission on the shared channel.

S12: The UE receives from the eNodeB of the mobile communicationsnetwork an indication of a subset of the predetermined number offrequency division multiplexed symbols in which the communicationsdevice should transmit the data on the shared channel. The indication ofthe subset of frequency division multiplexed symbols, in one example,can be transmitted on a broadcast signal or provided at call setup ormay be provided in response to each request for grant of uplink sharedchannel resources.

S14: The UE then transmits signals representing the data in the sharedchannel to occupy a smaller number of the frequency division multiplexedsymbols than the number which are available within the time period ofthe shared channel.

Various further aspects and features of the present disclosure aredefined in the appended claims. Various combinations of the features ofthe dependent claims may be made with those of the independent claimsother than the specific combinations recited for the claim dependency.Although embodiments of the present disclosure have been described withreference to LTE, it will be appreciated that other embodiments findapplication with other wireless communication systems such as UMTS.

The following numbered clauses provide further example aspects:

1. A communications device for transmitting data to or receiving datafrom a mobile communications network, the mobile communications networkincluding one or more network elements which are arranged to form awireless access interface for transmitting and receiving the data, thecommunications device comprising

a transmitter unit configured to transmit signals representing the dataon an up-link of the wireless access interface to the mobilecommunications network,

a receiver unit configured to receive signals representing the datatransmitted on a down-link from the mobile communications network viathe wireless access interface, the wireless access interface providing aplurality of communications resource elements across a frequency rangefor the down-link and the up-link, the communications resource elementsbeing formed by dividing sub-carriers at different frequencies into aplurality of time periods, one or more of the sub-carriers beingprovided to form, in the time domain, frequency division multiplexedsymbols, each of the time periods comprising a predetermined number ofthe frequency division multiplexed symbols, wherein the up-link includesa shared channel providing the communications resources for allocationto the communications device by the mobile communications network fortransmitting the data on the up-link to the mobile communicationsnetwork, the shared channel providing communications resources which areshared with other communications terminals and comprising in the timedomain, the predetermined number of frequency division multiplexedsymbols in each time period for allocation to the communications device,and

a controller configured to control the transmitter unit to transmit thesignals and the receiver unit to receive the signals to transmit orreceive the data, wherein the controller is configured to control thetransmitter unit and the receiver unit

to transmit to the mobile communications network a request to transmitdata in a smaller number of frequency division multiplexed symbols thanare available on the shared channel,

to receive from the mobile communications network an indication of asub-set of the predetermined number of frequency division multiplexedsymbols in which the communications device should transmit the data onthe shared channel, and

to transmit signals representing the data in the shared channel tooccupy a smaller number of frequency division multiplexed symbols thanthe number of the predetermined number of frequency division multiplexedsymbols of the time period of the shared channel.

2. A communications device according to clause 1, wherein the controlleris configured to transmit the signals representing the data in thesmaller number of frequency division multiplexed symbols within the timeperiod of the shared channel starting at a different one of thepredetermined number of frequency division multiplexed symbols, each ofthe different starting frequency division multiplexed symbolsrepresenting further information.

3. A communications device according to clause 1 or 2, wherein thecontroller is configured to transmit the signals representing the datawith one or more reference symbols included in the number of frequencydivision multiplexed symbols to assist in demodulating the receivedsignal to recover the data, and a position of the one or more referencesymbols within the transmitted frequency division multiplexed symbols isvaried between a plurality of locations within the transmitted symbols,each of the locations representing further information.

4. A communications device according to clause 2 or 3, wherein thefurther information forms part of the data being transmitted by thecontroller.

5. A communications device according to any of clauses 1 to 4, whereinthe shared channel comprises a plurality of frequency divisionmultiplexed symbols in the time domain and a plurality of sub-carriersin the frequency domain and transmission of the signalling informationincludes a contiguous sub-set of the frequency division multiplexedsymbols starting at one of the predetermined frequency divisionmultiplexed symbols.

6. A communications device according to any of clauses 1 to 5, whereinthe controller is configured to transmit the data by mapping datasymbols representing the frequency division multiplexed symbols bymodulating the sub-carriers of the shared channel with modulationsymbols representing the data symbols, the modulation order of themodulation symbols being so that the data can be transmitted in atemporal length which is less than the temporal length of the timeperiod of the shared channel.

7. A communications device according to any of clauses 1 to 6, whereinthe time period of the shared channel is formed from a sub-frame of aframe into which the up-link is divided.

8. A communications device according to clause 7, wherein the sharedchannel is formed from two time slots into which the sub-frame isdivided and the predetermined number of frequency division multiplexedsymbols is the number of symbols in one of the time slots.

9. A communications device according to any of clauses 1 to 9, whereinthe controller is configured in combination with the receiver unit

to receive control information from the mobile communications networkfor configuring the transmission of the signals representing the data inthe shared channel, whereby other communications devices can beconfigured to adapt transmissions of signals in the same shared channelwith the transmission of the signals representing the data by thecommunications device, and the controller is configured in combinationwith the transmitter unit

to configure the transmitter unit in accordance with the controlinformation received from the mobile communications network to transmitthe signals representing the data in the shared channel.

10. A method of transmitting data to or receiving data from a mobilecommunications network, the mobile communications network including oneor more network elements which are arranged to form a wireless accessinterface for transmitting and receiving the data, the method comprising

transmitting signals representing the data on an up-link of the wirelessaccess interface to the mobile communications network,

receiving signals representing the data transmitted on a down-link fromthe mobile communications network via the wireless access interface, thewireless access interface providing a plurality of communicationsresource elements across a frequency range for the down-link and theup-link, the communications resource elements being formed by dividingsub-carriers at different frequencies into a plurality of time periods,one or more of the sub-carriers being provided to form, in the timedomain, frequency division multiplexed symbols, each of the time periodscomprising a predetermined number of the frequency division multiplexedsymbols, wherein the up-link includes a shared channel providing thecommunications resources for allocation to the communications device bythe mobile communications network for transmitting the data on theup-link to the mobile communications network, the shared channelproviding communications resources which are shared with othercommunications terminals and comprising in the time domain, thepredetermined number of frequency division multiplexed symbols in eachtime period for allocation to the communications device, and

controlling the transmitting the signals and the receiving the signalsto transmit or receive the data, wherein the controlling thetransmitting includes

transmitting to the mobile communications network a request to transmitdata in a smaller number of frequency division multiplexed symbols thanare available on the shared channel,

receiving from the mobile communications network an indication of asub-set of the predetermined number of frequency division multiplexedsymbols in which the communications device should transmit the data onthe shared channel, and

transmitting signals representing the data in the shared channel tooccupy a smaller number of frequency division multiplexed symbols thanthe number of the predetermined number of frequency division multiplexedsymbols of the time period of the shared channel.

11. A method according to clause 10, wherein the controlling thetransmitting includes transmitting the signals representing the data inthe smaller number of frequency division multiplexed symbols within thetime period of the shared channel starting at a different one of thepredetermined number of frequency division multiplexed symbols, each ofthe different starting frequency division multiplexed symbolsrepresenting further information.

12. A method according to clause 10 or 11, wherein the controlling thetransmitting includes transmitting the signals representing the dataincludes transmitting one or more reference symbols included in thenumber of frequency division multiplexed symbols to assist indemodulating the received signal to recover the data, and

varying a position of the one or more reference symbol within thetransmitted frequency division multiplexed symbols between a pluralityof locations within the transmitted symbols, each of the locationsrepresenting further information.

13. A method according to clause 11 or 12, wherein the furtherinformation forms part of the data being transmitted by the controller.

14. An infrastructure equipment for forming part of a mobilecommunications network and providing a wireless access interface fortransmitting data to and receiving data from a communications device,the infrastructure equipment comprising

a transmitter unit configured to transmit signals representing the dataon a down-link of the wireless access interface to the mobilecommunications network,

a receiver unit configured to receive signals representing the datatransmitted on an up-link from the mobile communications network via thewireless access interface, the wireless access interface providing aplurality of communications resource elements across a frequency rangefor the down-link and the up-link, the communications resource elementsbeing formed by dividing sub-carriers at different frequencies into aplurality of time periods, one or more of the sub-carriers beingprovided to form, in the time domain, frequency division multiplexedsymbols, each of the time periods comprising a predetermined number ofthe frequency division multiplexed symbols, wherein the up-link includesa shared channel providing the communications resources for allocationto the communications device by the infrastructure equipment fortransmitting the data on the up-link to the infrastructure equipment,the shared channel providing communications resources which are sharedwith other communications terminals and comprising in the time domain,the predetermined number of frequency division multiplexed symbols ineach time period for allocation to the communications device, and

a controller configured to control the receiver unit to receive thesignals and the transmitter unit to transmit the signals to transmit orreceive the data, wherein the controller is configured to control thetransmitter unit and the receiver unit

to receive from a communications device a request to transmit data in asmaller number of frequency division multiplexed symbols than areavailable on the shared channel,

to transmit to the communications device an indication of a sub-set ofthe predetermined number of frequency division multiplexed symbols inwhich the communications device should transmit the data on the sharedchannel, and

to receive signals representing the data in the shared channel within asmaller number of frequency division multiplexed symbols than the numberof the predetermined number of frequency division multiplexed symbols ofthe time period of the shared channel.

15. An infrastructure equipment according to clause 14, wherein thecontroller is configured to receive the signals representing the data inthe smaller number of frequency division multiplexed symbols within thetime period of the shared channel starting at a different one of thepredetermined number of frequency division multiplexed symbols, each ofthe different starting frequency division multiplexed symbolsrepresenting further information.

16. An infrastructure equipment according to clause 14 or 15, whereinthe controller is configured to receive the signals representing thedata in the smaller number of frequency division multiplexed symbolswithin the time period of the shared channel, the received signalsrepresenting the data with one or more reference symbols included in thenumber of frequency division multiplexed symbols to assist indemodulating the received signal to recover the data, the one or morereference symbols transmitted with the data bearing symbols varying inlocation with respect to a position of the data bearing symbols, each ofthe locations representing further information, and

the controller is configured to detect the further information based onthe location of the one or more reference symbols.

The invention claimed is:
 1. A communications device for transmittingdata to or receiving data from a mobile communications network, themobile communications network including one or more network elementswhich are arranged to form a wireless access interface for transmittingand receiving the data, the communications device comprising: atransmitter configured to transmit signals representing the data on anup-link of the wireless access interface to the mobile communicationsnetwork, a receiver configured to receive signals representing the datatransmitted on a down-link from the mobile communications network viathe wireless access interface, the wireless access interface providing aplurality of communications resource elements across a frequency rangefor the down-link and the up-link, the communications resource elementsbeing formed by dividing sub-carriers at different frequencies into aplurality of time periods, one or more of the sub-carriers beingprovided to form, in the time domain, frequency division multiplexedsymbols, each of the time periods comprising a predetermined number ofthe frequency division multiplexed symbols, wherein the up-link includesa shared channel providing the communications resources for allocationto the communications device by the mobile communications network fortransmitting the data on the up-link to the mobile communicationsnetwork, the shared channel providing communications resources which areshared with other communications terminals and comprising in the timedomain, the predetermined number of frequency division multiplexedsymbols in each time period for allocation to the communications device,and a controller configured to control the transmitter to transmit thesignals and the receiver to receive the signals to transmit or receivethe data, wherein the controller is configured to control thetransmitter and the receiver to transmit to the mobile communicationsnetwork a request to transmit data in a smaller number of frequencydivision multiplexed symbols than are available on the shared channel,receive from the mobile communications network an indication of asub-set of the predetermined number of frequency division multiplexedsymbols in which the communications device should transmit the data onthe shared channel, and transmit signals representing the data in theshared channel to occupy a smaller number of frequency divisionmultiplexed symbols than the number of the predetermined number offrequency division multiplexed symbols of the time period of the sharedchannel, wherein the controller is configured to transmit the signalsrepresenting the data in the smaller number of frequency divisionmultiplexed symbols within the time period of the shared channelstarting at a different one of the predetermined number of frequencydivision multiplexed symbols, each of the different starting frequencydivision multiplexed symbols representing further information.
 2. Thecommunications device of claim 1, wherein the controller is configuredto transmit the signals representing the data with one or more referencesymbols included in the number of frequency division multiplexed symbolsto assist in demodulating the received signal to recover the data, and aposition of the one or more reference symbols within the transmittedfrequency division multiplexed symbols is varied between a plurality oflocations within the transmitted symbols, each of the locationsrepresenting further information.
 3. The communications device of claim1, wherein the further information forms part of the data beingtransmitted by the controller.
 4. The communications device of claim 1,wherein the shared channel comprises a plurality of frequency divisionmultiplexed symbols in the time domain and a plurality of sub-carriersin the frequency domain and transmission of the signaling informationincludes a contiguous sub-set of the frequency division multiplexedsymbols starting at one of the predetermined frequency divisionmultiplexed symbols.
 5. The communications device of claim 1, whereinthe controller is configured to transmit the data by mapping datasymbols representing the frequency division multiplexed symbols bymodulating the sub-carriers of the shared channel with modulationsymbols representing the data symbols, the modulation order of themodulation symbols being so that the data can be transmitted in atemporal length which is less than the temporal length of the timeperiod of the shared channel.
 6. The communications device of claim 1,wherein the time period of the shared channel is formed from a sub-frameof a frame into which the up-link is divided.
 7. The communicationsdevice of claim 6, wherein the shared channel is formed from two timeslots into which the sub-frame is divided and the predetermined numberof frequency division multiplexed symbols is the number of symbols inone of the time slots.
 8. The communications device of claim 1, whereinthe controller is configured in combination with the receiver to receivecontrol information from the mobile communications network forconfiguring the transmission of the signals representing the data in theshared channel, whereby other communications devices can be configuredto adapt transmissions of signals in the same shared channel with thetransmission of the signals representing the data by the communicationsdevice, and the controller is configured in combination with thetransmitter to configure the transmitter in accordance with the controlinformation received from the mobile communications network to transmitthe signals representing the data in the shared channel.
 9. A method oftransmitting data to or receiving data from a mobile communicationsnetwork, the mobile communications network including one or more networkelements which are arranged to form a wireless access interface fortransmitting and receiving the data, the method comprising: transmittingsignals representing the data on an up-link of the wireless accessinterface to the mobile communications network, receiving signalsrepresenting the data transmitted on a down-link from the mobilecommunications network via the wireless access interface, the wirelessaccess interface providing a plurality of communications resourceelements across a frequency range for the down-link and the up-link, thecommunications resource elements being formed by dividing sub-carriersat different frequencies into a plurality of time periods, one or moreof the sub-carriers being provided to form, in the time domain,frequency division multiplexed symbols, each of the time periodscomprising a predetermined number of the frequency division multiplexedsymbols, wherein the up-link includes a shared channel providing thecommunications resources for allocation to the communications device bythe mobile communications network for transmitting the data on theup-link to the mobile communications network, the shared channelproviding communications resources which are shared with othercommunications terminals and comprising in the time domain, thepredetermined number of frequency division multiplexed symbols in eachtime period for allocation to the communications device, and controllingthe transmitting the signals and the receiving the signals to transmitor receive the data, wherein the controlling the transmitting includestransmitting to the mobile communications network a request to transmitdata in a smaller number of frequency division multiplexed symbols thanare available on the shared channel, receiving from the mobilecommunications network an indication of a sub-set of the predeterminednumber of frequency division multiplexed symbols in which thecommunications device should transmit the data on the shared channel,and transmitting signals representing the data in the shared channel tooccupy a smaller number of frequency division multiplexed symbols thanthe number of the predetermined number of frequency division multiplexedsymbols of the time period of the shared channel, wherein thecontrolling the transmitting includes transmitting the signalsrepresenting the data in the smaller number of frequency divisionmultiplexed symbols within the time period of the shared channelstarting at a different one of the predetermined number of frequencydivision multiplexed symbols, each of the different starting frequencydivision multiplexed symbols representing further information.
 10. Themethod of claim 9, wherein the controlling the transmitting includestransmitting the signals representing the data includes transmitting oneor more reference symbols included in the number of frequency divisionmultiplexed symbols to assist in demodulating the received signal torecover the data, and varying a position of the one or more referencesymbol within the transmitted frequency division multiplexed symbolsbetween a plurality of locations within the transmitted symbols, each ofthe locations representing further information.
 11. An infrastructureequipment for forming part of a mobile communications network andproviding a wireless access interface for transmitting data to andreceiving data from a communications device, the infrastructureequipment comprising: a transmitter configured to transmit signalsrepresenting the data on a down-link of the wireless access interface tothe mobile communications network, a receiver configured to receivesignals representing the data transmitted on an up-link from the mobilecommunications network via the wireless access interface, the wirelessaccess interface providing a plurality of communications resourceelements across a frequency range for the down-link and the up-link, thecommunications resource elements being formed by dividing sub-carriersat different frequencies into a plurality of time periods, one or moreof the sub-carriers being provided to form, in the time domain,frequency division multiplexed symbols, each of the time periodscomprising a predetermined number of the frequency division multiplexedsymbols, wherein the up-link includes a shared channel providing thecommunications resources for allocation to the communications device bythe infrastructure equipment for transmitting the data on the up-link tothe infrastructure equipment, the shared channel providingcommunications resources which are shared with other communicationsterminals and comprising in the time domain, the predetermined number offrequency division multiplexed symbols in each time period forallocation to the communications device, and a controller configured tocontrol the receiver to receive the signals and the transmitter totransmit the signals to transmit or receive the data, wherein thecontroller is configured to control the transmitter and the receiver toreceive from a communications device a request to transmit data in asmaller number of frequency division multiplexed symbols than areavailable on the shared channel, transmit to the communications devicean indication of a sub-set of the predetermined number of frequencydivision multiplexed symbols in which the communications device shouldtransmit the data on the shared channel, and receive signalsrepresenting the data in the shared channel within a smaller number offrequency division multiplexed symbols than the number of thepredetermined number of frequency division multiplexed symbols of thetime period of the shared channel, wherein the controller is configuredto receive the signals representing the data in the smaller number offrequency division multiplexed symbols within the time period of theshared channel starting at a different one of the predetermined numberof frequency division multiplexed symbols, each of the differentstarting frequency division multiplexed symbols representing furtherinformation.
 12. The infrastructure equipment of claim 11, wherein thecontroller is configured to receive the signals representing the data inthe smaller number of frequency division multiplexed symbols within thetime period of the shared channel, the received signals representing thedata with one or more reference symbols included in the number offrequency division multiplexed symbols to assist in demodulating thereceived signal to recover the data, the one or more reference symbolstransmitted with the data bearing symbols varying in location withrespect to a position of the data bearing symbols, each of the locationsrepresenting further information, and the controller is configured todetect the further information based on the location of the one or morereference symbols.